Magnetic buckling assembly

ABSTRACT

A magnetic buckling assembly includes a male buckling component, a female buckling component, a first locking portion, a second locking portion, an operating component, a first magnetic component and a second magnetic component. The first magnetic component magnetically attracts or magnetically repulses the second magnetic component during a connecting process of the male buckling component and the female buckling component along a connecting direction. The first magnetic component magnetically attracts the second magnetic component for preventing separation of the male buckling component and the female buckling component or magnetically repulses the second magnetic component for promoting the separation of the male buckling component and the female buckling component when the operating component is operated to disengage the first locking portion from the second locking portion for allowing the separation of the male buckling component and the female buckling component.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a buckling assembly, and moreparticularly, to a magnetic buckling assembly.

2. Description of the Prior Art

With development of economy and advancement of technology, there aremore and more consumer goods available in the market for bringingconvenience in people's lives. A baby carrier is one of these consumergoods.

It is well known that a baby carrier usually includes multiple strapsand multiple buckling assemblies for quickly connecting or disconnectingthe straps.

Currently, a conventional buckling assembly usually includes a malebuckling component, a female buckling component and a releasing button.The male buckling component is connected to a strap, and the femalebuckling component is connected to another strap, so that the straps canbe connected to each other by engagement of the male buckling componentand the female buckling component. The releasing button is fordisengaging the male buckling component from the female bucklingcomponent to disconnect the straps.

However, the conventional buckling assembly has drawbacks of difficultoperation and complicated structure.

Therefore, there is a need to provide an improved buckling assembly witheasy operation and compact structure for solving the aforementionedproblems.

SUMMARY OF THE INVENTION

It is an objective of the present invention to provide a magneticbuckling assembly with easy operation and compact structure.

In order to achieve the aforementioned objective, the present inventiondiscloses a magnetic buckling assembly including a male bucklingcomponent, a female buckling component, a first locking portion, asecond locking portion, an operating component, a first magneticcomponent and a second magnetic component. The first locking portion isdisposed on one of the male buckling component and the female bucklingcomponent. The second locking portion is disposed on the other one ofthe male buckling component and the female buckling component and forengaging with the first locking portion. The operating component ismovably disposed on the other one of the male buckling component and thefemale buckling component. The first magnetic component is disposed onthe female buckling component. The second magnetic component is disposedon the male buckling component and for magnetically cooperating with thefirst magnetic component. The male buckling component is connected tothe female buckling component along a connecting direction by engagementof the first locking portion and the second locking portion. The firstmagnetic component magnetically attracts or magnetically repulses thesecond magnetic component during a connecting process of the malebuckling component and the female buckling component along theconnecting direction, and the first magnetic component magneticallyattracts the second magnetic component for preventing separation of themale buckling component and the female buckling component ormagnetically repulses the second magnetic component for promoting theseparation of the male buckling component and the female bucklingcomponent when the operating component is operated to disengage thefirst locking portion from the second locking portion for allowing theseparation of the male buckling component and the female bucklingcomponent.

According to an embodiment of the present invention, the first lockingportion is a resilient structure. The second locking portion includes anabutting structure and an engaging structure. The abutting structurepushes and resiliently deforms the first locking portion during theconnecting process of the male buckling component and the femalebuckling component along the connecting direction, so that the firstlocking portion slides to engage with the engaging structure, and theoperating component is operated to resiliently deform the first lockingportion to disengage the first locking portion from the engagingstructure.

According to an embodiment of the present invention, the first lockingportion includes at least one resilient arm and at least one engaginghead for engaging with the engaging structure. The at least one engaginghead is connected to the at least one resilient arm. The at least oneresilient arm biases the at least one engaging head to engage with theengaging structure. The abutting structure pushes the at least oneengaging head to resiliently deform the at least one resilient armduring the connecting process of the male buckling component and thefemale buckling component along the connecting direction, so that the atleast one engaging head slides to engage with the engaging structure,and the operating component is operated to resiliently deform the atleast one resilient arm to disengage the at least one engaging head fromthe engaging structure.

According to an embodiment of the present invention, the operatingcomponent is operated to push the at least one resilient arm along anoperating direction parallel to the connecting direction to resilientlydeform the at least one resilient arm along a deforming directionintersecting with the connecting direction to disengage the at least oneengaging head from the engaging structure.

According to an embodiment of the present invention, the operatingcomponent includes at least one abutting inclined surface inclinedrelative to the connecting direction, and the operating component isoperated to push and resiliently deform the at least one resilient armby the at least one abutting inclined surface.

According to an embodiment of the present invention, the at least oneengaging head surrounds the engaging structure. The at least oneabutting inclined surface is inclined away from the abutting structurefrom inside to outside, and the operating component is operated to pushand resiliently spread the at least one resilient arm outwardly by theat least one abutting inclined surface.

According to an embodiment of the present invention, the first lockingportion includes at least two resilient arms surrounding the secondlocking portion and at least two engaging heads, and each of the atleast two resilient arms is connected to a corresponding one of the atleast two engaging heads.

According to an embodiment of the present invention, an at least oneexpanding leg extends from the operating component along the connectingdirection, and the at least one abutting inclined surface is formed onthe at least one expanding leg.

According to an embodiment of the present invention, the first lockingportion includes at least one driven inclined surface disposed on aproximal end of the at least one resilient arm connected to the at leastone engaging head for cooperating with the at least one abuttinginclined surface, and the operating component is operated to push andresiliently deform the at least one resilient arm by cooperation of theat least one abutting inclined surface and the at least one driveninclined surface.

According to an embodiment of the present invention, a recess is formedon the proximal end of the at least one resilient arm connected to theat least one engaging head. The at least one expanding leg extends intothe recess. The at least one driven inclined surface is formed on a wallof the recess, and the at least one abutting inclined surface is formedon an end of the at least one expanding leg.

According to an embodiment of the present invention, the at least oneabutting inclined surface is formed on an end of the at least oneexpanding leg and cooperates with a distal end of the at least oneresilient arm away from the at least one engaging head.

According to an embodiment of the present invention, the magneticbuckling assembly further includes a resilient component for providing arecovering resilient force to recover the operating component.

According to an embodiment of the present invention, an end of theabutting structure comprises a first inclined structure inclinedrelative to the connecting direction. The at least one engaging headincludes a second inclined structure cooperating with the first inclinedstructure, and the abutting structure slides across the at least oneengaging head to engage the engaging structure with the at least oneengaging head by cooperation of the first inclined structure and thesecond inclined structure.

According to an embodiment of the present invention, the at least oneengaging head is a hook, and the engaging structure is a hook slotcorresponding to the hook.

According to an embodiment of the present invention, a firstinstallation chamber is formed on the female buckling component. Asecond installation chamber is formed on the male buckling component.The first magnetic component is installed into the first installationchamber, and the second magnetic component is installed into the secondinstallation chamber.

According to an embodiment of the present invention, the firstinstallation chamber is aligned with the second installation chamberalong the connecting direction.

According to an embodiment of the present invention, the firstinstallation chamber or the second installation chamber is formed insidethe second locking portion.

According to an embodiment of the present invention, at least one of thefirst magnetic component and the second magnetic component is apermanent magnetic component.

According to an embodiment of the present invention, the operatingcomponent is a circular button or a rectangular button.

According to an embodiment of the present invention, the one of the malebuckling component and the female buckling component comprises an outercover and a buckling body disposed inside the outer cover, and theoperating component movably passes through the outer cover along theconnecting direction.

According to an embodiment of the present invention, each of the otherone of the male buckling component and the female buckling component andthe outer cover includes at least one assembling portion for installingat least one strap, and a through hole is formed on the at least oneassembling portion for allowing the at least one strap to passtherethrough.

According to an embodiment of the present invention, the second lockingportion is a column structure. The male buckling component is rotatablerelative to the female buckling component around the second lockingportion. The other one of the male buckling component and the femalebuckling component includes two assembling portions opposite to eachother, and positions of the two assembling portions relative to theouter cover are adjustable by rotation of the male buckling componentrelative to the female buckling component.

According to an embodiment of the present invention, a disposing hole isformed on a first side of the outer cover away from the second lockingportion. The operating component is disposed inside the disposing hole,and a connecting hole is formed on a second side of the outer coveradjacent to the second locking portion for allowing the second lockingportion to pass therethrough.

According to an embodiment of the present invention, at least one ribprotrudes from the outer cover and adjacent to a lateral wall of theouter cover.

According to an embodiment of the present invention, the magneticbuckling assembly further includes a protecting component disposed onthe one of the male buckling component and the female buckling componentand movable relative to the one of the male buckling component and thefemale buckling component between a first position and a secondposition. The protecting component restrains the operating componentfrom disengaging the first locking portion from the second lockingportion when the protecting component is located at the first position,and the operating component is allowed to disengage the first lockingportion from the second locking portion when the protecting component islocated at the second position.

According to an embodiment of the present invention, the protectingcomponent engages with the operating component when the protectingcomponent is located at the first position, and the protecting componentdisengages from the operating component when the protecting component islocated at the second position.

According to an embodiment of the present invention, the protectingcomponent covers the operating component when the protecting componentis located at the first position, and the operating component is exposedwhen the protecting component is located at the second position.

According to an embodiment of the present invention, the operatingcomponent is slidably disposed on the one of the male buckling componentand the female buckling component along an operating direction parallelto the connecting direction, and the protecting component is slidablydisposed on the one of the male buckling component and the femalebuckling component along a sliding direction intersecting with theconnecting direction.

According to an embodiment of the present invention, the protectingcomponent is disposed on the one of the male buckling component and thefemale buckling component and slidable or rotatable relative to the oneof the male buckling component and the female buckling component betweenthe first position and the second position.

According to an embodiment of the present invention, the magneticbuckling assembly further includes a recovering component for biasingthe protecting component to slide or rotate to the first position.

According to an embodiment of the present invention, the protectingcomponent includes a covering portion and a guiding portion connected tothe covering portion. The covering portion selectively covers or exposesthe operating component. The guiding portion is movably disposed on theone of the male buckling component and the female buckling component,and the covering portion and the guiding portion are misaligned witheach other along the connecting direction.

According to an embodiment of the present invention, at least one of theguiding portion and the covering portion is a hollow structure with anopening toward the other one of the male buckling component and thefemale buckling component.

According to an embodiment of the present invention, the protectingcomponent includes a first end and a second end. The first end of theprotecting component is a resilient structure and connected to the oneof the male buckling component and the female buckling component, andthe second end of the protecting component is configured to cover orexpose the operating component.

According to an embodiment of the present invention, at least oneclearance structure is formed on at least one of the second lockingportion and the one of the male buckling component and the femalebuckling component for allowing the second locking portion to slidealong an offsetting direction intersecting with the connecting directionto an offsetting position after the first locking portion engages withthe second locking portion, and the one of the male buckling componentand the female buckling component includes an abutting portion forabutting against the second locking portion for preventing theseparation of the male buckling component and the female bucklingcomponent when the second locking portion is located at the offsettingposition.

According to an embodiment of the present invention, the second lockingportion includes at least one first partition for engaging with thefirst locking portion and at least one second partition for abuttingagainst the abutting portion. The at least one clearance structureincludes a first clearance structure formed on the second lockingportion, and the first clearance structure is a clearance slot.

According to an embodiment of the present invention, the one of the malebuckling component and the female buckling component includes an outercover and a buckling body disposed inside the outer cover. The firstlocking portion is disposed on the buckling body. A connecting hole isformed on a side of the outer cover for allowing the second lockingportion to pass therethrough. The at least one clearance structurefurther includes a second clearance structure formed on the outer cover.The second clearance structure is a clearance hole communicated with theconnecting hole, and the abutting portion is formed on the outer cover.

According to an embodiment of the present invention, the lateral wall ofthe clearance slot abuts against an inner wall of the clearance holewhen the second locking portion is located at the offsetting position.

According to an embodiment of the present invention, a contactingsurface of the lateral wall of the clearance slot and a contactingsurface of the inner wall of the clearance hole are flat surfaces.

According to an embodiment of the present invention, the connecting holeis arc-shaped hole, and the clearance hole is a rectangular hole andcommunicated with the arc-shape hole.

According to an embodiment of the present invention, the abuttingportion is located on an inner surface of the outer cover adjacent tothe inner wall of the clearance hole.

According to an embodiment of the present invention, a notch is formedon the buckling body and corresponding to the clearance hole. The notchis parallel to the connecting direction. The at least one secondpartition of the second locking portion slides into the notch during anoffsetting process of the second locking portion.

According to an embodiment of the present invention, two clearancestructures are formed on the second locking portion and opposite to eachother.

In summary, the present invention utilizes engagement of the firstlocking portion and the second locking portion for connecting the malebuckling component to the female buckling component. Furthermore, thepresent invention further utilizes magnetic cooperation of the firstmagnetic component and the second magnetic component for securingconnection between the male buckling component and the female bucklingcomponent. Therefore, the connection between the male buckling componentand the female buckling component is more reliable. If the firstmagnetic component is configured to magnetically attract the secondmagnetic component, the male buckling component can still be connectedto the female buckling component in a condition that the first lockingportion and the second locking portion are disengaged from each otherdue to an operational mistake of the operating component, which providesbetter safety in use and prevents the male buckling component or thefemale buckling component from falling and missing due to disengagementof the male buckling component or the female buckling component. On theother hand, if the first magnetic component is configured tomagnetically repulse the second magnetic component, the male bucklingcomponent can be connected to the female buckling component because thefirst locking portion and the second locking portion can be driven toabut against each other by magnetic repulsion of the first magneticcomponent and the second magnetic component, which makes the connectionof the male buckling component and the female buckling component morereliable. Furthermore, the male buckling component can be driven to beseparated from the female buckling component by the magnetic repulsionof the first magnetic component and the second magnetic component in acondition that the first locking portion and the second locking portionare disengaged from each other by the operating component, whichprovides convenience in use. Besides, the magnetic buckling assembly ofthe present invention also has an advantage of compact structure.

These and other objectives of the present invention will no doubt becomeobvious to those of ordinary skill in the art after reading thefollowing detailed description of the preferred embodiment that isillustrated in the various figures and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 and FIG. 2 are schematic diagrams of a magnetic buckling assemblyat different views according to a first embodiment of the presentinvention.

FIG. 3 is an exploded diagram of the magnetic buckling assemblyaccording to the first embodiment of the present invention.

FIG. 4 is an internal structural diagram of the magnetic bucklingassembly according to the first embodiment of the present invention.

FIG. 5 is a diagram of the magnetic buckling assembly withoutillustrating an outer cover according to the first embodiment of thepresent invention.

FIG. 6 is a partial diagram of a female buckling component according tothe first embodiment of the present invention.

FIG. 7 and FIG. 8 are schematic diagrams of a magnetic buckling assemblyat different views according to a second embodiment of the presentinvention.

FIG. 9 is an internal structural diagram of the magnetic bucklingassembly according to the second embodiment of the present invention.

FIG. 10 is a partial exploded diagram of the magnetic buckling assemblyaccording to the second embodiment of the present invention.

FIG. 11 and FIG. 12 are exploded diagrams of a magnetic bucklingassembly at different views according to a third embodiment of thepresent invention.

FIG. 13 is an internal structural diagram of the magnetic bucklingassembly according to the third embodiment of the present invention.

FIG. 14 is a schematic diagram of a magnetic buckling assembly accordingto a fourth embodiment of the present invention.

FIG. 15 is a sectional diagram of the magnetic buckling assemblyaccording to the fourth embodiment of the present invention.

FIG. 16 to FIG. 18 are schematic diagrams of the magnetic bucklingassembly in different states according to the fourth embodiment of thepresent invention.

FIG. 19 is a partial diagram of the magnetic buckling assembly accordingto the fourth embodiment of the present invention.

FIG. 20 is an exploded diagram of the magnetic buckling assemblyaccording to the fourth embodiment of the present invention.

FIG. 21 is a partial diagram of a female buckling component according tothe fourth embodiment of the present invention.

FIG. 22 is a diagram of a male buckling component according to thefourth embodiment of the present invention.

FIG. 23 and FIG. 24 are schematic diagrams of a magnetic bucklingassembly at different views according to a fifth embodiment of thepresent invention.

FIG. 25 and FIG. 26 are exploded diagrams of the magnetic bucklingassembly at different views according to the fifth embodiment of thepresent invention.

FIG. 27 is a diagram of a male buckling component according to the fifthembodiment of the present invention.

FIG. 28 is a diagram of an outer cover according to the fifth embodimentof the present invention.

FIG. 29 is a partial diagram of a female buckling component according tothe fifth embodiment of the present invention.

FIG. 30 is a diagram of an operating component according to the fifthembodiment of the present invention.

FIG. 31 and FIG. 32 are internal structural diagrams of the magneticbuckling assembly at different views according to the fifth embodimentof the present invention.

DETAILED DESCRIPTION

In the following detailed description of the preferred embodiments,reference is made to the accompanying drawings which form a part hereof,and in which is shown by way of illustration specific embodiments inwhich the invention may be practiced. In this regard, directionalterminology, such as “top,” “bottom,” “front,” “back,” etc., is usedwith reference to the orientation of the Figure(s) being described. Thecomponents of the present invention can be positioned in a number ofdifferent orientations. As such, the directional terminology is used forpurposes of illustration and is in no way limiting. Accordingly, thedrawings and descriptions will be regarded as illustrative in nature andnot as restrictive.

Please refer to FIG. 1 to FIG. 4. FIG. 1 and FIG. 2 are schematicdiagrams of a magnetic buckling assembly 100 at different viewsaccording to a first embodiment of the present invention. FIG. 3 is anexploded diagram of the magnetic buckling assembly 100 according to thefirst embodiment of the present invention. FIG. 4 is an internalstructural diagram of the magnetic buckling assembly 100 according tothe first embodiment of the present invention. As shown in FIG. 1 toFIG. 4, the magnetic buckling assembly 100 includes a female bucklingcomponent 1, a male buckling component 2, an operating component 3, afirst magnetic component 4, a second magnetic component 5, a firstlocking portion 1 a and a second locking portion 2 a. In thisembodiment, the first locking portion 1 a and the first magneticcomponent 4 can be disposed on the female buckling component 1, and thesecond locking portion 2 a and the second magnetic component 5 can bedisposed on the male buckling component 2. The male buckling component 2can be connected to the female buckling component 1 along a connectingdirection by engagement of the first locking portion 1 a and the secondlocking portion 2 a. The operating component 3 can be movably disposedon the female buckling component 1 for disengaging the first lockingportion 1 a from the second locking portion 2 a to allow separation ofthe male buckling component 2 and the female buckling component 1.

Furthermore, the first magnetic component 4 can be configured tomagnetically attract the second magnetic component 5. Therefore, thefirst magnetic component 4 can magnetically attract the second magneticcomponent 5 during a connecting process of the male buckling component 2and the female buckling component 1 along the connecting direction,which achieves a purpose of a quick connection of the male bucklingcomponent 2 and the female buckling component 1. Furthermore, the firstmagnetic component 4 can magnetically attract the second magneticcomponent 5 for preventing separation of the male buckling component 2and the female buckling component 1 when the operating component 3 isoperated to disengage the first locking portion 1 a from the secondlocking portion 2 a for allowing the separation of the male bucklingcomponent 2 and the female buckling component 1. However, it is notlimited thereto. For example, in another embodiment, the first magneticcomponent can be configured to magnetically repulse the second magneticcomponent for driving the first locking portion to abut against thesecond locking portion when the male buckling component is connected tothe female buckling component, which makes the connection of the malebuckling component and the female buckling component more reliable.Furthermore, the male buckling component can be driven to be separatedfrom the female buckling component by magnetic repulsion of the firstmagnetic component and the second magnetic component when the firstlocking portion and the second locking portion are disengaged from eachother by the operating component, which provides convenience in use.

Specifically, in this embodiment, the female buckling component 1 canfurther include an outer cover 6 and a buckling body 1 b. The bucklingbody 1 b is disposed inside the outer cover 6, and the first lockingportion 1 a is disposed on the buckling body 1 b. The operatingcomponent 3 movably passes through the outer cover 6 along theconnecting direction, i.e., a vertical direction in FIG. 4. Preferably,in this embodiment, the operating component 3 can be a circular buttonfor allowing a user to disengage the first locking portion 1 a from thesecond locking portion 2 a by pressing the operating component 3 easily.A disposing hole 61 is formed on a first side of the outer cover 6 awayfrom the second locking portion 2 a, i.e., an upper side of the outercover 6 shown in FIG. 4, for allowing the operating component 3 to bedisposed therein, and a connecting hole 62 is formed on a second side ofthe outer cover 6 adjacent to the second locking portion 2 a, i.e., alower side of the outer cover 6 shown in FIG. 4, for allowing the secondlocking portion 2 a to pass therethrough to engage with the firstlocking portion 1 a.

The outer cover 6 can not only make cooperation of the male bucklingcomponent 2 and the female buckling component 1 more reliable but alsoprevent wear damage of the male buckling component 2 or the femalebuckling component 1 caused by dust from environment, which extends aservice life of the magnetic buckling assembly 100 and improvesaesthetic appearance of the magnetic buckling assembly 100. However, itis not limited to this embodiment. For example, in another embodiment,the outer cover of the female buckling component can be omitted, i.e.,the operating component can be directly disposed on the buckling body ofthe female buckling component. Alternatively, in another embodiment, themale buckling component can include an outer cover and a buckling bodydisposed inside the outer cover. The first locking portion and thesecond locking portion can be respectively disposed on the buckling bodyof the male buckling component and the buckling body of the femalebuckling component. The operating component can be correspondinglymovably disposed on the outer cover of the male buckling component fordisengaging the first locking portion from the second locking portion.

Please refer to FIG. 3 to FIG. 6. FIG. 5 is a diagram of the magneticbuckling assembly 100 without illustrating the outer cover 6 accordingto the first embodiment of the present invention. FIG. 6 is a partialdiagram of the female buckling component 1 according to the firstembodiment of the present invention. As shown in FIG. 3 to FIG. 6, thefirst locking portion 1 a is a resilient structure. The second lockingportion 2 a includes an abutting structure 21 and an engaging structure22. The abutting structure 21 can push and resiliently deform the firstlocking portion 1 a during the connecting process of the male bucklingcomponent 2 and the female buckling component 1 along the connectingdirection, so that the first locking portion 1 a can slide to engagewith the engaging structure 22. Therefore, the abutting structure 21allows the engaging structure 22 to engage with the first lockingportion 1 a easily and smoothly. Furthermore, the operating component 3can be operated to resiliently deform the first locking portion 1 a todisengage the first locking portion 1 a from the engaging structure 22.

Specifically, the first locking portion 1 a includes two resilient arms11 and two engaging heads 12. Each engaging head 12 is connected to thecorresponding resilient arm 11 for engaging with the engaging structure22. Preferably, as shown in FIG. 3, in this embodiment, each resilientarm 11 and the corresponding engaging head 12 can be an integrallyformed structure, and the two engaging heads 12 can be hung inside amiddle portion of the female buckling component 1 by the two resilientarms 11, so that the two resilient arms 11 can reliably drive the twoengaging heads 12 to move. The two resilient arms 11 are for biasing thetwo engaging heads 12 to engage with the engaging structure 22.Therefore, the abutting structure 21 pushes the two engaging heads 12 toresiliently deform the two resilient arms 11 during the connectingprocess of the male buckling component 2 and the female bucklingcomponent 1 along the connecting direction, so that the two engagingheads 12 can slide to engage with the engaging structure 22, whichachieves a purpose of automatic engagement of the male bucklingcomponent 2 and the female buckling component 1 during the connectingprocess of the male buckling component 2 and the female bucklingcomponent 1.

Furthermore, the operating component 3 is operated to resiliently deformthe two resilient arms 11 to disengage the two engaging heads 12 fromthe engaging structure 22. Preferably, in this embodiment, the operatingcomponent 3 can be operated to push the two resilient arms 11 along anoperating direction parallel to the connecting direction to resilientlydeform the two resilient arms 11 along two deforming directionsintersecting with the connecting direction to disengage the two engagingheads 12 from the engaging structure 22, which facilitates disengagementof the two engaging heads 12 and the engaging structure 22.

Preferably, in this embodiment, the two resilient arms 11 can surroundthe second locking portion 2 a cooperatively, and the two engaging heads12 can surround the engaging structure 22 cooperatively. Suchconfiguration can make engagement of the two engaging heads 12 and theengaging structure 22 more reliable, which secures the connection of themale buckling component 2 and the female buckling component 1. However,it is not limited to this embodiment. For example, in anotherembodiment, the numbers of the resilient arm and the engaging head alsocan be one, three, four or five.

Preferably, in this embodiment, each engaging head 12 can be a hook, andthe engaging structure 22 can be a hook slot corresponding to the hook,so that the male buckling component 2 can be connected to the femalebuckling component 1 firmly by the engagement of the hook and the hookslot . Furthermore, the buckling body 1 b of the female bucklingcomponent 1 can be a hollow structure, and the female buckling component1 can further include a supporting arm 14 located in a middle portion ofthe buckling body 1 b of the female buckling component 1 and between thetwo resilient arms 111 and connected to two opposite sides of thebuckling body 1 b of the female buckling component 1 for reinforcingstructural strength of the female buckling component 1.

As shown in FIG. 3 to FIG. 6, an end of the abutting structure 21includes a first inclined structure 211 inclined relative to theconnecting direction. Each engaging head 12 includes a second inclinedstructure 121 cooperating with the first inclined structure 211. Theabutting structure 21 can slide across the two engaging heads 12 toengage the engaging structure 22 with the two engaging heads 12 easilyby cooperation of the first inclined structure 211 and the secondinclined structures 121, which facilitates the connection of the malebuckling component 2 and the female buckling component 1.

Furthermore, the operating component 3 includes two abutting inclinedsurfaces 31 inclined relative to the connecting direction, and theoperating component 3 can be operated to push and resiliently deform thetwo resilient arms 11 by the two abutting inclined surfaces 31, so as todisengage the two engaging heads 12 from the engaging structure 22.Since the two engaging heads 12 surround the engaging structure 22cooperatively, each abutting inclined surface 31 can be configured to beinclined away from the corresponding engaging head 12 from inside tooutside. Therefore, the operating component 3 can be operated to pushand resiliently spread the two resilient arms 11 outwardly by the twoabutting inclined surfaces 31, which achieves a purpose of driving thetwo engaging heads 12 to move outwardly to disengage from the engagingstructure 22 by the two resilient arms 11. However, it is not limited tothis embodiment. For example, in another embodiment, each engaging headalso can be driven to move inwardly to disengage from the engagingstructure by the two resilient arms.

Besides, two expanding legs 32 extend from the operating component 3along the connecting direction, and each abutting inclined surface 31 isformed on the corresponding expanding leg 32. The first locking portion1 a includes two driven inclined surfaces 111. Each driven inclinedsurface 111 is disposed on a proximal end of the corresponding resilientarm 11 connected to the corresponding engaging head 12 for cooperatingwith the corresponding abutting inclined surface 31. The operatingcomponent 3 can be operated to push and resiliently deform the tworesilient arms 11 by cooperation of the two abutting inclined surfaces31 and the two driven inclined surfaces 111, so as to disengage the twoengaging heads 12 from the engaging structure 22. Preferably, in thisembodiment, a recess 112 can be formed on the proximal end of eachresilient arm 11 connected to the corresponding engaging head 12. Eachexpanding leg 32 extends into the corresponding recess 112. Each driveninclined surface 111 is formed on a wall of the corresponding recess112. Each abutting inclined surface 31 is formed on an end of thecorresponding expanding leg 32. Such configuration allows the operatingcomponent 3 to be operated easily to push and deform the two resilientarms 11. Furthermore, since the two expanding legs 32 can directlycooperate with the two driven inclined surfaces 111 on the two recesses112 adjacent to the proximal ends of the two resilient arms 11, itallows the two resilient arms 11 to deform quickly, so as to quicklydisengage the two engaging heads 12 from the engaging structure 22.Besides, the operating component 3 can be driven to recover by the tworesilient arms 11 because of the cooperation of the abutting inclinedsurfaces 31 of the expanding legs 32 and the proximal ends of theresilient arms 11. However, it is not limited thereto. For example, inanother embodiment, the numbers of abutting inclined surface, theexpanding leg, the recess and the driven inclined surface also can beone if there is only one resilient arm.

As shown in FIG. 3, FIG. 4 and FIG. 6, a first installation chamber 13is formed on the female buckling component 1, and a second installationchamber 23 is formed on the male buckling component 2. The firstmagnetic component 4 is installed into the first installation chamber13, and the second magnetic component 5 is installed into the secondinstallation chamber 23, so that the first magnetic component 4 and thesecond magnetic component 5 can be hidden inside the female bucklingcomponent 1 and the male buckling component 2, respectively.Specifically, in this embodiment, the first installation chamber 13 canbe aligned with the second installation chamber 23 along the connectingdirection, so as to maximize the magnetic cooperation of the firstmagnetic component 4 and the second magnetic component 5, which achievesa purpose of the quick connection of the male buckling component 2 andthe female buckling component 1 and a purpose of preventing separationof the male buckling component 2 and the female buckling component 1. Inthis embodiment, the second installation chamber 23 can be formed insidethe second locking portion 2 a, the first installation chamber 13 can beformed inside the middle portion of the female buckling component 1, andmore specifically in a middle portion of the supporting arm 14, whichmakes structure of the magnetic buckling assembly 100 reasonable andcompact for achieving a purpose of saving material.

Furthermore, in this embodiment, each of the first magnetic component 4and the second magnetic component 5 can be a permanent magneticcomponent. However, it is not limited to this embodiment. For example,in another embodiment, one of the first magnetic component and thesecond magnetic component can be a permanent magnetic component, and theother one of the first magnetic component and the second magneticcomponent can be a conductive magnetic component, such as a metalstructure. Preferably, a thickness of the first magnetic component 4 canbe from 3.0 to 5.5 millimeters. More preferably, the thickness of thefirst magnetic component 4 can be 3.0, 3.8, 4.5, 5.0 or 5.5 millimeters.In this embodiment, the thickness of the first magnetic component 4 canbe 3.8 millimeters. It should be noticed that, in another embodiment,the first installation chamber can be formed inside the second lockingportion if the second locking portion is disposed on the female bucklingcomponent.

As shown in FIG. 1, FIG. 2, FIG. 3 and FIG. 5, each of the male bucklingcomponent 2 and the outer cover 6 includes at least one assemblingportion for installing at least one strap. Preferably, the male bucklingcomponent 2 can include two assembling portions opposite to each other,and the outer cover 6 can include one assembling portion. The assemblingportion of the outer cover 6 can be always misaligned with one of thetwo assembling portions of the male buckling component 2 for easyassembly of the straps. Specifically, a through hole 24 can be formed oneach of the two assembling portions of the male buckling component 2,and a through hole 63 can be formed on the assembling portions of theouter cover 6. The male buckling component 2 can be fixed to a firstcloth surface, which is not shown in figures, by passing the strapsthrough the two assembling portions of the male buckling component 2.The female buckling component 1 can be fixed on a second cloth surface,which is not shown in figures, bypassing the straps through theassembling portion of the outer cover 6. Therefore, the first clothsurface can be detachably connected to the second cloth surface by themagnetic buckling assembly 100.

In this embodiment, the second locking portion 2 a can be a columnstructure, so that the male buckling component 2 is rotatable relativeto the female buckling component 1 around the second locking portion 2a, which brings flexibility in use. Positions of the two assemblingportions relative to the outer cover 6 are adjustable by rotation of themale buckling component 2 relative to the female buckling component 1,and therefore, any one of the two assembling portions of the malebuckling component 2 can be used together with the assembling portion ofthe outer cover 6. If one of the two assembling portions of the malebuckling component 2 is broken, the other one of two assembling portionsof the male buckling component 2 can be used together with theassembling portion of the outer cover 6 by the rotation of the malebuckling component 2 relative to the female buckling component 1, whichmakes the magnetic buckling assembly 100 more durable.

As shown in FIG. 1 to FIG. 6, operational principle of the magneticbuckling component 100 of this embodiment is provided as follows. Whenit is desired to separate or disconnect the male buckling component 2from the female buckling component 1, the operating component 3 can bepressed downwardly to drive the expanding legs 32 to push the driveninclined surfaces 111 on the recesses 112 on the resilient arms 11. Bythe cooperation of the abutting inclined surfaces 31 on the expandinglegs 32 and the driven inclined surfaces 111 on the recesses 112, theresilient arms 11 can resiliently spread outwardly to drive the engagingheads 12 connected to the resilient arms 11 to move outwardly todisengage from the engaging structure 22 of the second locking portion 2a for allowing the separation of the female buckling component 1 and themale buckling component 2. At this moment, the male buckling component 2is still connected to the female buckling component 1 by magneticattraction of the first magnetic component 4 and the second magneticcomponent 5. Afterwards, as long as the female buckling component 1 andthe male buckling component 2 are pulled away from each other toovercome the magnetic attraction of the first magnetic component 4 andthe second magnetic component 5, the female buckling component 1 can beseparated or disconnected from the male buckling component 2.

When it is desired to connect the male buckling component 2 to thefemale buckling component 1, it only has to move the male bucklingcomponent 2 and the female buckling component 1 to align the secondlocking portion 2 a with the connecting hole 62 on the outer cover 6 andthen to move the male buckling component 2 and the female bucklingcomponent 1 toward each other. By the magnetic attraction of the firstmagnetic component 4 and the second magnetic component 5, the abuttingstructure 21 of the second locking portion 2 a can slide across theengaging heads 12, so that the engaging structure 22 and the engagingheads 12 can be engaged with each other, which achieves a purpose of theconnection of the male buckling component 2 and the female bucklingcomponent 1 as shown in FIG. 4.

Please refer to FIG. 7 to FIG. 10. FIG. 7 and FIG. 8 are schematicdiagrams of a magnetic buckling assembly 100 a at different viewsaccording to a second embodiment of the present invention. FIG. 9 is aninternal structural diagram of the magnetic buckling assembly 100 aaccording to the second embodiment of the present invention. FIG. 10 isa partial exploded diagram of the magnetic buckling assembly 100 aaccording to the second embodiment of the present invention. As shown inFIG. 7 to FIG. 10, different from the first embodiment, a plurality ofribs 64 protrude from two opposite lateral walls of the outer cover 6 ofthis embodiment for providing friction to facilitate the user to operatethe magnetic buckling assembly 100 a easily. However, it is not limitedto this embodiment. For example, in another embodiment, the number ofthe rib can be one. Furthermore, in this embodiment, the abuttinginclined surface 31 on each expanding leg 32 is located adjacent to adistal end of the corresponding resilient arm 11 away from thecorresponding engaging head 12 for cooperating with the distal end ofthe corresponding resilient arm 11. In other words, each expanding leg32 is located between the corresponding resilient arm 11 and thesupporting arm 14 and directly cooperates with the distal end of thecorresponding resilient arm 11, and therefore, the driven inclinedsurface 111 and the recess 112 can be omitted in this embodiment.Furthermore, the supporting arm 14 of this embodiment can be configuredto engage with a gap between the two expanding legs 32 spaced from eachother.

Besides, in this embodiment, since each expanding leg 32 directlycooperates with the distal end of the corresponding resilient arm 11,recovering forces generated by the two resilient arms 11 might be toosmall to recover the operating component 3. Therefore, the magneticbuckling assembly 100 a can further include a resilient component 7 forproviding a recovering resilient force to recover the operatingcomponent 3. Preferably, the resilient component 7 can be an elasticspring abutting between the operating component 3 and the femalebuckling component 1 and be aligned with the first installation chamber13. However, it is not limited thereto. For example, in anotherembodiment, the resilient component also can be a resilient structuremade of plastic material. Besides, the thickness of the first magneticcomponent 4 of this embodiment can be 5.0 millimeters.

Other structure of the magnetic buckling assembly 100 a of thisembodiment is similar to the one of the magnetic buckling assembly 100of the first embodiment. Detailed description is omitted herein forsimplicity.

As shown in FIG. 7 to FIG. 10, operational principle of the magneticbuckling assembly 100 a of this embodiment is provided as follows. Whenit is desired to separate or disconnect the male buckling component 2from the female buckling component 1, the operating component 3 can bepressed downwardly to resiliently compress the resilient component 7.During the aforementioned process, the abutting inclined surfaces 31 onthe expanding legs 32 of the operating component 3 cooperate with thedistal ends of the resilient arms 11 away from the engaging head 12, sothat the resilient arms 11 spread outwardly to drive the engaging heads12 connected to the resilient arms 11 to move outwardly to disengagefrom the engaging structure 22 of the second locking portion 2 a forallowing the separation of the male buckling component 2 and the femalebuckling component 1. At this moment, the male buckling component 2 isstill connected to the female buckling component 1 by the magneticattraction of the first magnetic component 4 and the second magneticcomponent 5. Afterwards, as long as the female buckling component 1 andthe male buckling component 2 are pulled away from each other toovercome the magnetic attraction of the first magnetic component 4 andthe second magnetic component 5, the female buckling component 1 can beseparated or disconnected from the male buckling component 2.

When it is desired to connect the male buckling component 2 to thefemale buckling component 1, it only has to move the male bucklingcomponent 2 and the female buckling component 1 to align the secondlocking portion 2 a with the connecting hole 62 on the outer cover 6 andthen to move the male buckling component 2 and the female bucklingcomponent 1 toward each other. By the magnetic attraction of the firstmagnetic component 4 and the second magnetic component 5, the abuttingstructure 21 of the second locking portion 2 a can slide across theengaging heads 12, so that the engaging structure 22 and the engagingheads 12 can be engaged with each other, which achieves a purpose of theconnection of the male buckling component 2 and the female bucklingcomponent 1.

Please refer to FIG. 11 to FIG. 13. FIG. 11 and FIG. 12 are explodeddiagrams of a magnetic buckling assembly 100 b at different viewsaccording to a third embodiment of the present invention. FIG. 13 is aninternal structural diagram of the magnetic buckling assembly 100 baccording to the third embodiment of the present invention. As shown inFIG. 11 to FIG. 13, different from the aforementioned embodiments, theoperating component 3 of this embodiment can be a rectangular button.Furthermore, the rib can be omitted in this embodiment. Besides, theresilient component 7 of this embodiment can abut between the operatingcomponent 3 and the female buckling component 1 and be misaligned withthe first installation chamber 13.

Other structure and operational principle of the magnetic bucklingassembly 100 b of this embodiment are similar to the ones of themagnetic buckling assembly 100 a of the second embodiment. Detaileddescription is omitted herein for simplicity.

Please refer to FIG. 14 to FIG. 22. FIG. 14 is a schematic diagram of amagnetic buckling assembly 100 c according to a fourth embodiment of thepresent invention. FIG. 15 is a sectional diagram of the magneticbuckling assembly 100 c according to the fourth embodiment of thepresent invention. FIG. 16 to FIG. 18 are schematic diagrams of themagnetic buckling assembly 100 c in different states according to thefourth embodiment of the present invention. FIG. 19 is a partial diagramof the magnetic buckling assembly 100 c according to the fourthembodiment of the present invention. FIG. 20 is an exploded diagram ofthe magnetic buckling assembly 100 c according to the fourth embodimentof the present invention. FIG. 21 is a partial diagram of the femalebuckling component 1 according to the fourth embodiment of the presentinvention. FIG. 22 is a diagram of the male buckling component 2according to the fourth embodiment of the present invention. As shown inFIG. 14 to FIG. 22, different from the aforementioned embodiments, themagnetic buckling assembly 100 c of this embodiment further includes aprotecting assembly 8. The protecting assembly 8 includes a protectingcomponent 82 slidably disposed on the female buckling component 1 alonga sliding direction intersecting with the connecting direction andmovable relative to the female buckling component 1 between a firstposition and a second position. Preferably, in this embodiment, asliding slot 65 can be formed on the first side of the outer cover 6away from the second locking portion 2 a, i.e., the upper side of theouter cover 6, and the protecting component 82 can be slidably disposedinside the sliding slot 65 and slidably switched between the firstposition and the second position. The protecting component 82 canrestrain the operating component 3 from disengaging the first lockingportion 1 a from the second locking portion 2 a when the protectingcomponent 82 is located at the first position, and the operatingcomponent 3 is allowed to disengage the first locking portion 1 a fromthe second locking portion 2 a when the protecting component 82 islocated at the second position. However, it is not limited to thisembodiment. For example, in another embodiment, the protecting componentalso can be rotatably disposed on the male buckling component and movebetween the first position and the second position by rotation when theoperating component is disposed on the male buckling component.

In this embodiment, the protecting component 82 includes a first end anda second end. The first end of the protecting component 82 is aresilient structure, such as a resilient arm or a resilient leg, andconnected to the female buckling component 1, so that the deformed firstend of the protecting component 82 can bias the second end of theprotecting component 82 to recover. The second end of the protectingcomponent 82 is configured to cover the operating component 3 forpreventing the operating component 3 from being operated when theprotecting component 82 is located at the first position. The second endof the protecting component 82 is configured to expose the operatingcomponent 3 for allowing the operating component 3 to be operated whenthe protecting component 82 is located at the second position. However,it is not limited to this embodiment. Any structure which can allow orprevent operation of the operation component 3 is included within thescope of the present invention. For example, in another embodiment, theprotecting component also can be configured to engage with the operatingcomponent for preventing the operating component from being operatedwhen the protecting component is located at the first position. Theprotecting component can be configured to disengage from the operatingcomponent for allowing the operating component to be operated when theprotecting component is located at the second position.

Preferably, the protecting assembly 8 of the magnetic buckling assembly100 c can further include a recovering component 81 for biasing theprotecting component 82 to slide to the first position. The recoveringcomponent 81 is arranged along an arrangement direction intersectingwith the connecting direction. The recovering component 81 can be anelastic spring abutting between the protecting component 82 and thefemale buckling component 1. Specifically, the protecting component 82includes a covering portion 821 and a guiding portion 822 connected tothe covering portion 821. The covering portion 821 selectively covers orexposes the operating component 3. The guiding portion 822 is movablydisposed on the female buckling component 1, and the covering portion821 and the guiding portion 822 are misaligned with each other along theconnecting direction to form a step-shaped structure. The coveringportion 821 can be guided by the guiding portion 822 to move to thefirst position to cover the operating component 3. Preferably, in thisembodiment, each of the guiding portion 822 and the covering portion 821can be a hollow structure with an opening toward the male bucklingcomponent 2 to facilitate the covering portion 821 to cover theoperating component 3 and improve aesthetic appearance of the magneticbuckling assembly 100 c. However, it is not limited to this embodiment.For example, in another embodiment, when the protecting component andthe operating component can be disposed on the male buckling component,the recovering component can be disposed between the male bucklingcomponent and the guiding portion of the protecting component.

Other structure and operational principle of the magnetic bucklingassembly 100 c of this embodiment are similar to the ones described inthe aforementioned embodiments. Detailed description is omitted hereinfor simplicity.

Please refer to FIG. 23 to FIG. 32. FIG. 23 and FIG. 24 are schematicdiagrams of a magnetic buckling assembly 100 d at different viewsaccording to a fifth embodiment of the present invention. FIG. 25 andFIG. 26 are exploded diagrams of the magnetic buckling assembly 100 d atdifferent views according to the fifth embodiment of the presentinvention. FIG. 27 is a diagram of the male buckling component 2according to the fifth embodiment of the present invention. FIG. 28 is adiagram of the outer cover 6 according to the fifth embodiment of thepresent invention. FIG. 29 is a partial diagram of the female bucklingcomponent 1 according to the fifth embodiment of the present invention.FIG. 30 is a diagram of the operating component 3 according to the fifthembodiment of the present invention. FIG. 31 and FIG. 32 are internalstructural diagrams of the magnetic buckling assembly 100 d at differentviews according to the fifth embodiment of the present invention. Asshown in FIG. 23 to FIG. 32, different from the aforementionedembodiments, the female buckling component 1 of this embodiment furtherincludes a supporting cover 15 disposed inside the first installationchamber 13 for covering and supporting the first magnetic component 4.Furthermore, two first clearance structures 9 a are formed on the secondlocking portion 2 a. The female buckling component 1 includes anabutting portion 16 for abutting against the second locking portion 2 afor preventing the separation of the male buckling component 2 and thefemale buckling component 1 when the second locking portion 2 a islocated at the offsetting position. Preferably, in this embodiment, eachfirst clearance structure 9 a can be a clearance slot, and the twoclearance slots can be opposite to each other and spaced from each otheralong a direction parallel to an offsetting direction intersecting withthe connecting direction. The second locking portion 2 a can include twofirst partitions 2 a 1 and two second partitions 2 a 2. The two firstpartitions 2 a 1 can be opposite to each other and spaced from eachother along a direction perpendicular to the offsetting direction. Thetwo second partitions 2 a 2 can be opposite to each other and spacedfrom each other along the direction parallel to the offsettingdirection. That is, each second partition 2 a 2 is adjacent to andlocated between the two second partitions 2 a 1. The first partitions 2a 1 can engage with the first locking portion 1 a. The abutting portion16 can abut against one of the two second partitions 2 a 2, which cansave time of alignment of the male buckling component 2 and the femalebuckling component 1 and bring convenience in use. However, the numbersof the clearance slot, the first partition 2 a 1 and the secondpartition 2 a 2 are not limited to this embodiment.

Furthermore, a second clearance structure 9 b is formed on the outercover 6 of the female buckling component 1. Preferably, in thisembodiment, the second clearance structure 9 b can be a clearance holecommunicated with the connecting hole 62, and the abutting portion 16 isformed on the outer cover 6 of the female buckling component 1. Afterthe second locking portion 2 a passes through the connecting hole 62 toengage with the first locking portion 1 a, the second locking portion 2a can slide toward the clearance hole to the offsetting position.Preferably, the abutting portion 16 is located on an inner surface ofthe outer cover 6 adjacent to an inner wall of the clearance hole, whichallows the abutting portion 16 to abut against the corresponding secondpartition 2 a 2 quickly during an offsetting process of the secondlocking portion 2 a.

Furthermore, contacting surfaces of the lateral wall of the twoclearance slots and a contacting surface of the inner wall of theclearance hole can be flat surfaces, so that the contacting surface ofthe inner wall of the clearance hole can be attached to and abut againstthe contacting surface of the lateral wall of the correspondingclearance slot when the second locking portion 2 a is located at theoffsetting position, which effectively prevents accidental disengagementof the male buckling component 2 and the female buckling component 1.However, it is not limited to this embodiment. For example, thecontacting surface of the lateral wall of the clearance slot and thecontacting surface of the inner wall of the clearance hole can be curvedsurfaces. Furthermore, the connecting hole can preferably be anarc-shaped hole, and the clearance hole can preferably be a rectangularhole and communicated with the arc-shape hole.

However, it is not limited to this embodiment. Any structure or anyconfiguration, which allows the second locking portion 2 a to slidealong the offsetting direction intersecting with the connectingdirection to the offsetting position for preventing disengagement of themale buckling component 2 and the female buckling component 1 after thefirst locking portion 1 a engages with the second locking portion 2 a,is included within the scope of the present invention. For example, inanother embodiment, at least one clearance structure can be formed on atleast one of the second locking portion and the female bucklingcomponent for allowing the second locking portion to slide along theoffsetting direction intersecting with the connecting direction to theoffsetting position after the first locking portion engages with thesecond locking portion. Alternatively, at least one clearance structurecan be formed on the male buckling component if the second lockingportion is disposed on the female buckling component.

Besides, preferably, in this embodiment, a notch 17 can be formed on thebuckling body 1 b and corresponding to the clearance hole. The notch 17is parallel to the connecting direction. The second partition 2 a 2 ofthe second locking portion 2 a can slide into the notch 17 during anoffsetting process of the second locking portion 2 a. In other words,the notch 17 allows the second partition 2 a 2 to slide withoutobstruction during the offsetting process of the second locking portion.

Other structure and operational principle of the magnetic bucklingassembly 100 d of this embodiment are similar to the ones described inthe aforementioned embodiments. Detailed description is omitted hereinfor simplicity.

In contrast to the prior art, the present invention utilizes engagementof the first locking portion and the second locking portion forconnecting the male buckling component to the female buckling component.Furthermore, the present invention further utilizes magnetic cooperationof the first magnetic component and the second magnetic component forsecuring connection between the male buckling component and the femalebuckling component. Therefore, the connection between the male bucklingcomponent and the female buckling component is more reliable. If thefirst magnetic component is configured to magnetically attract thesecond magnetic component, the male buckling component can still beconnected to the female buckling component in a condition that the firstlocking portion and the second locking portion are disengaged from eachother due to an operational mistake of the operating component, whichprovides better safety in use and prevents the male buckling componentor the female buckling component from falling and missing due todisengagement of the male buckling component or the female bucklingcomponent. On the other hand, if the first magnetic component isconfigured to magnetically repulse the second magnetic component, themale buckling component can be connected to the female bucklingcomponent because the first locking portion and the second lockingportion can be driven to abut against each other by magnetic repulsionof the first magnetic component and the second magnetic component, whichmakes the connection of the male buckling component and the femalebuckling component more reliable. Furthermore, the male bucklingcomponent can be driven to be separated from the female bucklingcomponent by the magnetic repulsion of the first magnetic component andthe second magnetic component in a condition that the first lockingportion and the second locking portion are disengaged from each other bythe operating component, which provides convenience in use. Besides, themagnetic buckling assembly of the present invention also has anadvantage of compact structure.

Those skilled in the art will readily observe that numerousmodifications and alterations of the device and method may be made whileretaining the teachings of the invention. Accordingly, the abovedisclosure should be construed as limited only by the metes and boundsof the appended claims.

What is claimed is:
 1. A magnetic buckling assembly comprising: a malebuckling component; a female buckling component; a first locking portiondisposed on one of the male buckling component and the female bucklingcomponent; a second locking portion disposed on the other one of themale buckling component and the female buckling component and forengaging with the first locking portion; an operating component movablydisposed on the other one of the male buckling component and the femalebuckling component; a first magnetic component disposed on the femalebuckling component; and a second magnetic component disposed on the malebuckling component and for magnetically cooperating with the firstmagnetic component; wherein the male buckling component is connected tothe female buckling component along a connecting direction by engagementof the first locking portion and the second locking portion, the firstmagnetic component magnetically attracts or magnetically repulses thesecond magnetic component during a connecting process of the malebuckling component and the female buckling component along theconnecting direction, and the first magnetic component magneticallyattracts the second magnetic component for preventing separation of themale buckling component and the female buckling component ormagnetically repulses the second magnetic component for promoting theseparation of the male buckling component and the female bucklingcomponent when the operating component is operated to disengage thefirst locking portion from the second locking portion for allowing theseparation of the male buckling component and the female bucklingcomponent.
 2. The magnetic buckling assembly of claim 1, wherein thefirst locking portion is a resilient structure, the second lockingportion comprises an abutting structure and an engaging structure, theabutting structure pushes and resiliently deforms the first lockingportion during the connecting process of the male buckling component andthe female buckling component along the connecting direction, so thatthe first locking portion slides to engage with the engaging structure,and the operating component is operated to resiliently deform the firstlocking portion to disengage the first locking portion from the engagingstructure.
 3. The magnetic buckling assembly of claim 2, wherein thefirst locking portion comprises at least one resilient arm and at leastone engaging head for engaging with the engaging structure, the at leastone engaging head is connected to the at least one resilient arm, the atleast one resilient arm biases the at least one engaging head to engagewith the engaging structure, the abutting structure pushes the at leastone engaging head to resiliently deform the at least one resilient armduring the connecting process of the male buckling component and thefemale buckling component along the connecting direction, so that the atleast one engaging head slides to engage with the engaging structure,and the operating component is operated to resiliently deform the atleast one resilient arm to disengage the at least one engaging head fromthe engaging structure.
 4. The magnetic buckling assembly of claim 3,wherein the operating component is operated to push the at least oneresilient arm along an operating direction parallel to the connectingdirection to resiliently deform the at least one resilient arm along adeforming direction intersecting with the connecting direction todisengage the at least one engaging head from the engaging structure. 5.The magnetic buckling assembly of claim 4, wherein the operatingcomponent comprises at least one abutting inclined surface inclinedrelative to the connecting direction, and the operating component isoperated to push and resiliently deform the at least one resilient armby the at least one abutting inclined surface.
 6. The magnetic bucklingassembly of claim 5, wherein the at least one engaging head surroundsthe engaging structure, the at least one abutting inclined surface isinclined away from the abutting structure from inside to outside, andthe operating component is operated to push and resiliently spread theat least one resilient arm outwardly by the at least one abuttinginclined surface.
 7. The magnetic buckling assembly of claim 6, whereinthe first locking portion comprises at least two resilient armssurrounding the second locking portion and at least two engaging heads,and each of the at least two resilient arms is connected to acorresponding one of the at least two engaging heads.
 8. The magneticbuckling assembly of claim 6, wherein at least one expanding leg extendsfrom the operating component along the connecting direction, and the atleast one abutting inclined surface is formed on the at least oneexpanding leg.
 9. The magnetic buckling assembly of claim 8, wherein thefirst locking portion comprises at least one driven inclined surfacedisposed on a proximal end of the at least one resilient arm connectedto the at least one engaging head for cooperating with the at least oneabutting inclined surface, and the operating component is operated topush and resiliently deform the at least one resilient arm bycooperation of the at least one abutting inclined surface and the atleast one driven inclined surface.
 10. The magnetic buckling assembly ofclaim 9, wherein a recess is formed on the proximal end of the at leastone resilient arm connected to the at least one engaging head, the atleast one expanding leg extends into the recess, the at least one driveninclined surface is formed on a wall of the recess, and the at least oneabutting inclined surface is formed on an end of the at least oneexpanding leg.
 11. The magnetic buckling assembly of claim 8, whereinthe at least one abutting inclined surface is formed on an end of the atleast one expanding leg and cooperates with a distal end of the at leastone resilient arm away from the at least one engaging head.
 12. Themagnetic buckling assembly of claim 11, further comprising a resilientcomponent for providing a recovering resilient force to recover theoperating component.
 13. The magnetic buckling assembly of claim 3,wherein an end of the abutting structure comprises a first inclinedstructure inclined relative to the connecting direction, the at leastone engaging head comprises a second inclined structure cooperating withthe first inclined structure, and the abutting structure slides acrossthe at least one engaging head to engage the engaging structure with theat least one engaging head by cooperation of the first inclinedstructure and the second inclined structure.
 14. The magnetic bucklingassembly of claim 3, wherein the at least one engaging head is a hook,and the engaging structure is a hook slot corresponding to the hook. 15.The magnetic buckling assembly of claim 1, wherein a first installationchamber is formed on the female buckling component, a secondinstallation chamber is formed on the male buckling component, the firstmagnetic component is installed into the first installation chamber, andthe second magnetic component is installed into the second installationchamber.
 16. The magnetic buckling assembly of claim 15, wherein thefirst installation chamber is aligned with the second installationchamber along the connecting direction.
 17. The magnetic bucklingassembly of claim 15, wherein the first installation chamber or thesecond installation chamber is formed inside the second locking portion.18. The magnetic buckling assembly of claim 1, wherein at least one ofthe first magnetic component and the second magnetic component is apermanent magnetic component.
 19. The magnetic buckling assembly ofclaim 1, wherein the operating component is a circular button or arectangular button.
 20. The magnetic buckling assembly of claim 1,wherein the one of the male buckling component and the female bucklingcomponent comprises an outer cover and a buckling body disposed insidethe outer cover, and the operating component movably passes through theouter cover along the connecting direction.
 21. The magnetic bucklingassembly of claim 20, wherein each of the other one of the male bucklingcomponent and the female buckling component and the outer covercomprises at least one assembling portion for installing at least onestrap, and a through hole is formed on the at least one assemblingportion for allowing the at least one strap to pass therethrough. 22.The magnetic buckling assembly of claim 21, wherein the second lockingportion is a column structure, the male buckling component is rotatablerelative to the female buckling component around the second lockingportion, the other one of the male buckling component and the femalebuckling component comprises two assembling portions opposite to eachother, and positions of the two assembling portions relative to theouter cover are adjustable by rotation of the male buckling componentrelative to the female buckling component.
 23. The magnetic bucklingassembly of claim 21, wherein a disposing hole is formed on a first sideof the outer cover away from the second locking portion, the operatingcomponent is disposed inside the disposing hole, and a connecting holeis formed on a second side of the outer cover adjacent to the secondlocking portion for allowing the second locking portion to passtherethrough.
 24. The magnetic buckling assembly of claim 21, wherein atleast one rib protrudes from the outer cover and adjacent to a lateralwall of the outer cover.
 25. The magnetic buckling assembly of claim 1,further comprising a protecting component disposed on the one of themale buckling component and the female buckling component and movablerelative to the one of the male buckling component and the femalebuckling component between a first position and a second position, theprotecting component restraining the operating component fromdisengaging the first locking portion from the second locking portionwhen the protecting component is located at the first position, and theoperating component being allowed to disengage the first locking portionfrom the second locking portion when the protecting component is locatedat the second position.
 26. The magnetic buckling assembly of claim 25,wherein the protecting component engages with the operating componentwhen the protecting component is located at the first position, and theprotecting component disengages from the operating component when theprotecting component is located at the second position.
 27. The magneticbuckling assembly of claim 25, wherein the protecting component coversthe operating component when the protecting component is located at thefirst position, and the operating component is exposed when theprotecting component is located at the second position.
 28. The magneticbuckling assembly of claim 25, wherein the operating component isslidably disposed on the one of the male buckling component and thefemale buckling component along an operating direction parallel to theconnecting direction, and the protecting component is slidably disposedon the one of the male buckling component and the female bucklingcomponent along a sliding direction intersecting with the connectingdirection.
 29. The magnetic buckling assembly of claim 25, wherein theprotecting component is disposed on the one of the male bucklingcomponent and the female buckling component and slidable or rotatablerelative to the one of the male buckling component and the femalebuckling component between the first position and the second position.30. The magnetic buckling assembly of claim 29, further comprising arecovering component for biasing the protecting component to slide orrotate to the first position.
 31. The magnetic buckling assembly ofclaim 27, wherein the protecting component comprises a covering portionand a guiding portion connected to the covering portion, the coveringportion selectively covers or exposes the operating component, theguiding portion is movably disposed on the one of the male bucklingcomponent and the female buckling component, and the covering portionand the guiding portion are misaligned with each other along theconnecting direction.
 32. The magnetic buckling assembly of claim 31,wherein at least one of the guiding portion and the covering portion isa hollow structure with an opening toward the other one of the malebuckling component and the female buckling component.
 33. The magneticbuckling assembly of claim 25, wherein the protecting componentcomprises a first end and a second end, the first end of the protectingcomponent is a resilient structure and connected to the one of the malebuckling component and the female buckling component, and the second endof the protecting component is configured to cover or expose theoperating component.
 34. The magnetic buckling assembly of claim 1,wherein at least one clearance structure is formed on at least one ofthe second locking portion and the one of the male buckling componentand the female buckling component for allowing the second lockingportion to slide along an offsetting direction intersecting with theconnecting direction to an offsetting position after the first lockingportion engages with the second locking portion, and the one of the malebuckling component and the female buckling component comprises anabutting portion for abutting against the second locking portion forpreventing the separation of the male buckling component and the femalebuckling component when the second locking portion is located at theoffsetting position.
 35. The magnetic buckling assembly of claim 34,wherein the second locking portion comprises at least one firstpartition for engaging with the first locking portion and at least onesecond partition for abutting against the abutting portion, the at leastone clearance structure comprises a first clearance structure formed onthe second locking portion, and the first clearance structure is aclearance slot.
 36. The magnetic buckling assembly of claim 35, whereinthe one of the male buckling component and the female buckling componentcomprises an outer cover and a buckling body disposed inside the outercover, the first locking portion is disposed on the buckling body, aconnecting hole is formed on a side of the outer cover for allowing thesecond locking portion to pass therethrough, the at least one clearancestructure further comprises a second clearance structure formed on theouter cover, the second clearance structure is a clearance holecommunicated with the connecting hole, and the abutting portion isformed on the outer cover.
 37. The magnetic buckling assembly of claim36, wherein the lateral wall of the clearance slot abuts against aninner wall of the clearance hole when the second locking portion islocated at the offsetting position.
 38. The magnetic buckling assemblyof claim 37, wherein a contacting surface of the lateral wall of theclearance slot and a contacting surface of the inner wall of theclearance hole are flat surfaces.
 39. The magnetic buckling assembly ofclaim 36, the connecting hole is arc-shaped hole, and the clearance holeis a rectangular hole and communicated with the arc-shape hole.
 40. Themagnetic buckling assembly of claim 36, wherein the abutting portion islocated on an inner surface of the outer cover adjacent to the innerwall of the clearance hole.
 41. The magnetic buckling assembly of claim36, wherein a notch is formed on the buckling body and corresponding tothe clearance hole, the notch is parallel to the connecting direction,the at least one second partition of the second locking portion slidesinto the notch during an offsetting process of the second lockingportion.
 42. The magnetic buckling assembly of claim 34, wherein twoclearance structures are formed on the second locking portion andopposite to each other.